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Main Authors: Matsuoka, Felipe Akio, Farina, Eduardo Moreno J. M., Serpa, Augusto Sarquis, Monteiro, Soraya, Ragazzini, Rodrigo, Abdala, Nitamar, Takahashi, Marcelo Straus, Kitamura, Felipe Campos
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.23066
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author Matsuoka, Felipe Akio
Farina, Eduardo Moreno J. M.
Serpa, Augusto Sarquis
Monteiro, Soraya
Ragazzini, Rodrigo
Abdala, Nitamar
Takahashi, Marcelo Straus
Kitamura, Felipe Campos
author_facet Matsuoka, Felipe Akio
Farina, Eduardo Moreno J. M.
Serpa, Augusto Sarquis
Monteiro, Soraya
Ragazzini, Rodrigo
Abdala, Nitamar
Takahashi, Marcelo Straus
Kitamura, Felipe Campos
contents Generative foundation models can remove visual artifacts through realistic image inpainting, but their impact on medical AI performance remains uncertain. Pediatric hand radiographs often contain non-anatomical markers, and it is unclear whether inpainting these regions preserves features needed for bone age and gender prediction. To evaluate the clinical reliability of generative model-based inpainting for artifact removal, we used the RSNA Bone Age Challenge dataset, selecting 200 original radiographs and generating 600 inpainted versions with gpt-image-1 using natural language prompts to target non-anatomical artifacts. Downstream performance was assessed with deep learning ensembles for bone age estimation and gender classification, using mean absolute error (MAE) and area under the ROC curve (AUC) as metrics, and pixel intensity distributions to detect structural alterations. Inpainting markedly degraded model performance: bone age MAE increased from 6.26 to 30.11 months, and gender classification AUC decreased from 0.955 to 0.704. Inpainted images displayed pixel-intensity shifts and inconsistencies, indicating structural modifications not corrected by simple calibration. These findings show that, although visually realistic, foundation model-based inpainting can obscure subtle but clinically relevant features and introduce latent bias even when edits are confined to non-diagnostic regions, underscoring the need for rigorous, task-specific validation before integrating such generative tools into clinical AI workflows.
format Preprint
id arxiv_https___arxiv_org_abs_2511_23066
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Evaluating the Clinical Impact of Generative Inpainting on Bone Age Estimation
Matsuoka, Felipe Akio
Farina, Eduardo Moreno J. M.
Serpa, Augusto Sarquis
Monteiro, Soraya
Ragazzini, Rodrigo
Abdala, Nitamar
Takahashi, Marcelo Straus
Kitamura, Felipe Campos
Computer Vision and Pattern Recognition
Artificial Intelligence
Generative foundation models can remove visual artifacts through realistic image inpainting, but their impact on medical AI performance remains uncertain. Pediatric hand radiographs often contain non-anatomical markers, and it is unclear whether inpainting these regions preserves features needed for bone age and gender prediction. To evaluate the clinical reliability of generative model-based inpainting for artifact removal, we used the RSNA Bone Age Challenge dataset, selecting 200 original radiographs and generating 600 inpainted versions with gpt-image-1 using natural language prompts to target non-anatomical artifacts. Downstream performance was assessed with deep learning ensembles for bone age estimation and gender classification, using mean absolute error (MAE) and area under the ROC curve (AUC) as metrics, and pixel intensity distributions to detect structural alterations. Inpainting markedly degraded model performance: bone age MAE increased from 6.26 to 30.11 months, and gender classification AUC decreased from 0.955 to 0.704. Inpainted images displayed pixel-intensity shifts and inconsistencies, indicating structural modifications not corrected by simple calibration. These findings show that, although visually realistic, foundation model-based inpainting can obscure subtle but clinically relevant features and introduce latent bias even when edits are confined to non-diagnostic regions, underscoring the need for rigorous, task-specific validation before integrating such generative tools into clinical AI workflows.
title Evaluating the Clinical Impact of Generative Inpainting on Bone Age Estimation
topic Computer Vision and Pattern Recognition
Artificial Intelligence
url https://arxiv.org/abs/2511.23066